TY - JOUR
T1 - Positional cloning utilizing genomic DNA microarrays
T2 - The Niemann-Pick Type C gene as a model system
AU - Stephan, Dietrich A.
AU - Chen, Yidong
AU - Jiang, Yuan
AU - Malechek, Lindsay
AU - Gu, Jessie Z.
AU - Robbins, Christiane M.
AU - Bittner, Michael L.
AU - Morris, Jill A.
AU - Carstea, Eugene
AU - Meltzer, Paul S.
AU - Adler, Karl
AU - Garlick, Russell
AU - Trent, Jeffrey M.
AU - Ashlock, Melissa A.
N1 - Funding Information:
We thank D. Leja for providing graphics assistance and P. Penchev, National Institute of Neurologic Disorders and Stroke, for his contributions to this study. J. Gu was supported by a grant from the Ara Parseghian Medical Research Foundation.
PY - 2000/5
Y1 - 2000/5
N2 - A major obstacle in positional cloning is identifying the specific mutated gene from within a large physical contig. Here we describe the application of DNA microarray technology to a defined genomic region (physical map) to identify: (i) exons without a priori sequence data and (ii) the disease gene based on differential gene expression in a recessive disorder. The feasibility was tested using resources from the positional cloning of the Neimann-Pick Type C (NP-C) disease gene, NPC1. To identify NPC1 exons and optimize the technology, an array was generated from genomic fragments of the 110-kb bacterial artificial chromosome, 108N2, which encodes NPC1. First, as a test case for blindly identifying exons, fluorescently labeled NPC1 cDNA identified 108N2 fragments that contained NPC1 exons, many of which also contained intronic sequences and could be used to determine part of the NPC1 genomic structure. Second, to demonstrate that the NPC1 disease gene could be identified based upon differential gene expression, subarrays of 108N2 fragments were hybridized with fluorescently labeled cDNA probes generated from total RNA from hamster cell lines differentially expressing NPC1. A probe derived from the NP-C cell line CT60 did not detect NPC1 exons or other genomic fragments from 108N2. In contrast, several NPC1 exons were detected by a probe generated from the non-NP-C cell line 911D5A13, which was derived from CT60, and expressed NPC1 as a consequence of stable transduction with a YAC that contains NPC1 and encompasses 108N2. Thus, the array technology identified NPC1 as a candidate gene based on a physical contig and differential NPC1 expression between NP-C and non-NP-C cells. This technique should facilitate gene identification when a physical contig exists for a region of interest and mutations result in changes in the mRNA level of the disease gene or portions thereof. (C) 2000 Academic Press.
AB - A major obstacle in positional cloning is identifying the specific mutated gene from within a large physical contig. Here we describe the application of DNA microarray technology to a defined genomic region (physical map) to identify: (i) exons without a priori sequence data and (ii) the disease gene based on differential gene expression in a recessive disorder. The feasibility was tested using resources from the positional cloning of the Neimann-Pick Type C (NP-C) disease gene, NPC1. To identify NPC1 exons and optimize the technology, an array was generated from genomic fragments of the 110-kb bacterial artificial chromosome, 108N2, which encodes NPC1. First, as a test case for blindly identifying exons, fluorescently labeled NPC1 cDNA identified 108N2 fragments that contained NPC1 exons, many of which also contained intronic sequences and could be used to determine part of the NPC1 genomic structure. Second, to demonstrate that the NPC1 disease gene could be identified based upon differential gene expression, subarrays of 108N2 fragments were hybridized with fluorescently labeled cDNA probes generated from total RNA from hamster cell lines differentially expressing NPC1. A probe derived from the NP-C cell line CT60 did not detect NPC1 exons or other genomic fragments from 108N2. In contrast, several NPC1 exons were detected by a probe generated from the non-NP-C cell line 911D5A13, which was derived from CT60, and expressed NPC1 as a consequence of stable transduction with a YAC that contains NPC1 and encompasses 108N2. Thus, the array technology identified NPC1 as a candidate gene based on a physical contig and differential NPC1 expression between NP-C and non-NP-C cells. This technique should facilitate gene identification when a physical contig exists for a region of interest and mutations result in changes in the mRNA level of the disease gene or portions thereof. (C) 2000 Academic Press.
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U2 - 10.1006/mgme.2000.2989
DO - 10.1006/mgme.2000.2989
M3 - Article
C2 - 10833327
AN - SCOPUS:0034043009
SN - 1096-7192
VL - 70
SP - 10
EP - 18
JO - Molecular genetics and metabolism
JF - Molecular genetics and metabolism
IS - 1
ER -